KR100539202B1 - Fault notification system and process using local area network - Google Patents

Abstract

The fault notification system of the present invention detects a non-operational state of a computer or other type of network and, when a non-operational state is detected, transmits a network message from the network device to a monitoring system or control console. If a network message is configured by the network device when the network device is in operation, it is preferably configured by the operating system before any problem is detected. Such network messages are stored in some non-volatile storage medium, such as in one embodiment of the BIOS memory. As a result, very limited operating system functionality must be copied into the network device's BIOS. Only messages that have actually been sent should be stored and commands are needed to send the messages. In some embodiments, the coprocessor is used to detect malfunctions via secondary buses, which are preferably leased lines. The coprocessor loads the relevant message into the transmit buffer and sends it to the monitoring system even when the computer's CPU is not running.

Description

Disability notification system and method using premises information and communication network {FAULT NOTIFICATION SYSTEM AND PROCESS USING LOCAL AREA NETWORK}

The present invention relates to a failure notification system and method using an on-premises information communication network (hereinafter referred to as a LAN).

In most modern organizations, most employees or members have their own personal computers. These computers are generally physically distributed throughout the organization's facilities, but are connected to each other through computer networks to enable information exchange. Many medium or large organizations also have people responsible for maintaining the network, performing tasks such as network management, installing new computers, and repairing already installed computers.

 As the use and function of a computer increases, the number of employees who depend on it increases, so it is desirable to reduce the downtime of the computer. As a result, the administrator should be dispatched to the failing computer so that failure notifications can be made as soon as possible.

The problem of fault notification is somewhat resolved in new remote-power-on systems. Such systems typically have an auxiliary power supply acting on the power supply line in addition to the main power supply for the computer. The network interface card is at least partially powered by the auxiliary power supply when the computer is turned off for some other reason. This partial power supply allows the network interface card to receive primitive messages from the network, such as remote power on commands. These commands are sent to the microcontroller in the computer which, upon receipt, typically activates the power-up sequence. Such a system remotely powers up and boots the computer, allowing the computer to operate or perform maintenance, for example when an employee returns to work in the morning.

In the case of the remote power on system, there is usually a mechanism for notifying the control console when a particular computer is not properly powered up. This feature is supported by loading the primitive operating system into memory that stores the basic input / output system (BIOS) so that the computer's central processing unit (CPU) can construct appropriate messages, load them into the transmit buffer of the network interface card, and send them to the control console. do.

There are many problems with existing fault notification protocols. First, the implementation of such a protocol is generally limited to machines with remote power on capability. Although the release of such machines is increasing, today such machines are still a small part of the computers sold. The second problem is that existing systems are relatively expensive, resulting in a significant cost increase in the overall price of the computer, because part of the operating system must be copied into the BIOS memory. This increases costs in two related ways. Additional memory for the BIOS is expensive, and the computer so configured is non-standard, increasing the cost in an increasingly customized environment. Another problem with existing systems is that the bus and BIOS of the central processing unit are working properly, but they provide failure notification only for limited kinds of problems if the boot-up fails. Such a system becomes useless if the bus, CPU, or BIOS fails.

The present invention provides a failure notification system and method for solving the above problems of the conventional system. The broadest aspect of the invention is a failure notification method (and system) for a device with a network as described in claim 1. Similar to a conventional fault notification system, the present invention detects an inoperational state of a computer or other type of network device, and transmits a network message from that network device to a monitoring system or control console when an inoperational state is detected. . However, the present invention differs from conventional systems in that network messages are configured by the network device when the network device is in operation, preferably before any problems are detected.

For example, a network, such as a packet, cell, or frame, constitutes a message in anticipation of an inoperable state of an operating system of a network device. This network message is then stored in some nonvolatile storage medium, such as the BIOS memory of the first embodiment. As a result, very limited operating system functionality must be copied into the network device's BIOS. Only messages that are actually sent should be stored, and commands are needed to send that message.

In a particular implementation, the network message identifies the network device to the monitoring system. Also, especially if the monitoring system does not have asset tracking information. It is useful to code the vendor or manufacturer of the network device in a network message. In addition, the network message contains information related to the failure status of the network device to identify the source of the problem.

In the first embodiment, in order to further limit the information required in the nonvolatile memory, network messages are sent continuously at relatively low duty cycles, for example, once every 5 minutes. As such, even if the monitoring system becomes inoperative due to a failure, it can then receive a network message when the monitoring system is activated.

In another embodiment, the failure notification system includes a nonvolatile memory accessible by a transmission system, such as a network interface card. Such a transmission system is configured to automatically transmit a network message at a predetermined time after detecting a power up of the network device. However, during normal operation this automatic transfer is disabled by the operating system after the boot-up operation has completed successfully.

The second embodiment is most easily by loading the network message into the network transmission buffer when the transmission system detects a power-on, and automatically sending the network message when the timing system times out, unless disabled by the operating system. Is implemented.

In a third embodiment, the fault notification system includes a coprocessor that can also perform other housekeeping functions such as detection of operating temperature and power supply voltage. Coprocessors are generally powered from an auxiliary power supply. If the coprocessor detects improper operation during boot-up or during normal operation, then the coprocessor loads the relevant message into the transmit buffer and sends it to the monitoring system even if the computer's CPU is not working. In this embodiment, since the system can benefit from the processing resources of the coprocessor, there is no need to preconfigure the message.

1 is a block diagram of a computer or other network device 100 having a failure notification system in accordance with a preferred embodiment of the present invention. As usual, the CPU 110 transmits the information received at the input / output (I / O) port via the bus 112 to various peripheral devices. The bus-accessible BIOS (Basic Input / Output System) memory 114 is an operating system from a server 128 whose CPU is via a network connection via another peripheral device (such as a hard drive 124) or a network interface card 116. Holds the instructions needed to load The BIOS memory 114 is a general nonvolatile CMOS RAM powered by the real time clock battery 122, or alternatively, may be an EEROM or flash memory. In addition, the BIOS memory 114 includes a general mass ROM memory.

The network 118 is connected to a monitoring system or control console 120. If the CPU 110 fails to load the operating system from the hard drive 124 or the server 128 via the network 118, the CPU is transferred to the network interface card 116 according to a preferred embodiment of the present invention. And access the BIOS 114 to retrieve network messages sent to the monitoring system 120.

2 is a flowchart illustrating a method for constructing and sending a network message in accordance with the present invention. When the computer 100 is fully operational, it monitors itself in step 210 to evaluate its configuration and health condition. Such functionality is typically enhanced as part of the operating system and includes detecting possible failure conditions, DARM capacity, disk write errors, and network communication errors, and tracking new / deleted peripherals such as hard drives or daughter cards. . This information is encoded and placed into a network message by the operating system in step 212, which is constructed according to the protocol of the network 118. In general, a network message is a packet having information encoded in a payload. The source address of the packet is the computer 100 itself and the destination address is a monitoring system. The configured message is stored in non-volatile BIOS memory 114 in step 214.

The message stored in the BIOS memory 114 is used when the computer 100 is in an inoperative state in step 216. The main example is when the computer fails to properly boot and load the operating system after powering up. If such a failure is detected, in step 218 the BIOS ROM instructs the CPU 110 to read the network message stored in the BIOS RAM 114. The network message is written to the transmit buffer T _X of the network interface card 116 (step 220) and sent to the monitoring system 120 at step 222.

Preferably the network message is continuously resent at a low duty cycle until the computer is reset. In one example, the network message is retransmitted after being delayed a few minutes, such as five minutes, at step 224. As such, if the monitoring system 120 is temporarily unavailable on the network 118, the network message is retransmitted repeatedly until the monitoring system receives to avoid the BIOS processing the response signal from the monitoring system. .

3 is a second embodiment of a failure notification system constructed in accordance with the principles of the present invention.

In the second embodiment, the failure notification system is tightly integrated with the network communication system. The network message is stored in non-volatile RAM 316, which is directly accessible by the network communication system, preferably on network interface card 116. This nonvolatile RAM 316 is also accessible by control circuitry 314 on the network interface card, which loads the network message into the transmission buffer T _X of the interface card.

4 is a block diagram showing the operation of the second embodiment. Similar to the first embodiment, the monitoring system, preferably under the operating system of the computer, monitors the state of the computer (step 210) and constructs a network message when the computer is running (step 212). However, the network message is stored in non-volatile RAM 316 in network interface card 116 at step 214.

The control circuit 314 of the network interface card 116 monitors the computer 100 during power up at step 410. If a failure is detected, the control circuit loads the network message into the transmission buffer Tx of the network interface card 116 (step 412). The control circuit also starts a timing routine with a software / firmware function or using a separate timing circuit at step 414. If the timer times out, the transmit buffer Tx receives a signal at step 418 and transmits a network message. The timer is disabled by a command from the operating system in step 416 only when the network device boots successfully. This prevents the transmit buffer from transmitting the network message (step 420). In another embodiment, the BIOS command may disable the transmission of network messages even if the operating system has not been successfully loaded so that the BIOS may send its own messages. In any case, the system effectively acts as a deadman switch so that network messages can be sent when the network device fails to disable network message transmission.

As in the first embodiment, the network message is repeatedly sent after being delayed in step 422. However, it may also be disabled by the system only when transmitted.

Referring to FIG. 3, in a preferred embodiment, the non-volatile RAM 316, the transfer buffer T _X , the phase lock loop 318, and the control circuit 314 of the network interface card 116 may be connected to the computer 100. Power is supplied by the auxiliary power supply 320. Many newer computers have two power supplies. The main power supply 126 converts the ac line current to power the system and has an output capacity of tens or hundreds of Watts. Auxiliary power supplies are used to continuously convert a fairly small amount of line power while the computer is connected to a power line. It is commonly used to power circuitry that controls a computer during power up and power down.

According to the present invention, the network interface card is at least partially powered by the auxiliary power supply 320. Thus, the transmission of the network message does not require normal operation of the main power supply 126. In addition, the transmission system can be powered continuously to detect the power-up state. 5 is a block diagram of a third embodiment of a failure notification system of the present invention. This embodiment additionally includes a microcontroller 510 that is powered from the auxiliary power supply 320. In many embodiments, such microcontrollers are used to monitor the health of the system, such as operating temperature 512 and voltages from mains supply 126. The microcontroller 510 is preferably connected via a separate low speed bus 516 to communicate with the CPU 110 and the chipset 514. One such bus is a two-wire bus called I ² C (integrated interconnect). This provides a mechanism by which the microcontroller 510 can directly monitor the CPU 110 and chipset 514 if the CPU's main bus 112 is not operational. The low speed bus 516 also communicates with a transmission buffer Tx of the network interface card 116. When the microcontroller 510 detects a malfunction state of the central processing unit, for example during boot up, the microcontroller loads a network message into the transmission buffer Tx and sends it to the monitoring system 112. The third embodiment can monitor widely arranged problems of computer systems. Since the microcontroller 510 operates depending on the auxiliary power supply 320, the microcontroller 510 can also detect problems of the main power supply 126. Furthermore, the microcontroller can also be used to identify specific failures of the chipset 514, the CPU 110, or other peripheral devices via the slow bus 516. Thus, the microcontroller may detect and notify if, for example, the CPU failed a self-test sequence upon power up.

In a first embodiment, the third embodiment stores the network message in a nonvolatile RAM 518 accessible by the microcontroller 510. However, since the third embodiment can benefit from the processing power of the microcontroller 510, it is not necessary to completely configure the network failure message while the system is operating normally. Instead, network messages can be constructed to process and send raw information acquired by the microcontroller 510 during a failure.

Although the present invention has been described in detail with reference to the preferred embodiments, it can be variously modified within the scope of the present invention can be fully understood by those skilled in the art.

According to the failure notification system and method of the present invention, the problem of the conventional failure notification system can be solved.

1 is a block diagram of a failure notification system according to an embodiment of the present invention.

2 is a flowchart of a failure notification method according to an embodiment of the present invention.

3 is a block diagram of a second embodiment of a failure notification system of the present invention;

4 is a flowchart of a second embodiment of a failure notification method of the present invention;

5 is a block diagram of a third embodiment of a failure notification system of the present invention.

Explanation of symbols on the main parts of the drawings

100: computer

110: CPU

112: bus

114: BIOS memory

116: network interface card

118: network

120: monitoring system

122: real time clock battery

124: hard drive

126: main power supply

128: server

314: control circuit

316: nonvolatile RAM

318: phase locked loop

320: auxiliary power supply

510: microcontroller

514: chipset

516: low speed bus

Claims (9)

In the failure notification method for a network device connected to a monitoring system via a computer network, Constructing a network message informing the non-operational state of the network device when the network device is in operation; Storing the network message; Sending the network message to the monitoring system Failure notification method comprising a. 2. The method of claim 1, wherein constructing the network message comprises including an identifier of the network device in the network message. 2. The method of claim 1, wherein constructing the network message comprises including a failure state of the network device in the network message. 2. The method of claim 1, further comprising continuously transmitting the network message until reset and transmitting the network message in a duty cycle of minutes. 2. The method of claim 1, further comprising storing the network message in basic input / output system memory, and when the operating system fails to boot properly, the basic input / output system sends the network message for transmission to the monitoring system. Instructing the central processor to load into the transmission system. The method of claim 1, further comprising: transmitting the network message at a predetermined time after detecting power up of the network device unless instructed to be disabled by an operating system and / or a basic input / output system, and the central processing unit is self-testing. And constructing a new network message in response to detecting a failure during the sequence and transmitting the new network message. The method of claim 1, further comprising: constructing the network message to a coprocessor that loads the network message into a transmission system of the network device, and wherein the coprocessor transmits the network message to the transmission system via a slow bus. And the coprocessor transmits the network message at a predetermined time after detecting power up of the network device unless instructed to be disabled by an operating system. A failure notification system for a network device including a central processor, comprising: An operating system running at the central processor of the network device, which constitutes a network message for informing a non-operational state of the operating system; A nonvolatile memory for holding the network message; A transmission system for transmitting the network message to a monitoring system in response to an inoperational state of the operating system Failure notification system comprising a. 9. The system of claim 8, further comprising a timing system that is enabled in response to power up of the network device, wherein the transmission system loads the network message into a transmission buffer of the transmission system in response to the power up. And send the network message when the timing system times out, unless the operating system is disabled.